# metric space

(redirected from*Metric topology*)

Also found in: Dictionary, Thesaurus.

## metric space

[′me·trik ′spās]## Metric Space

a set of objects (points) in which a metric is introduced. Any metric space is a topological space; all possible open spheres are taken as neighborhoods in the space; in this case, the set of all points *x* for which the distance *p(x, xo) < K* is said to be an open sphere of radius *K* with center at the point *XD-* The topology of a given set may vary as a function of the metric introduced in it. For example, the following two metrics may be introduced in the set of real functions that are defined and continuous in the interval [*a, b*] of the number axis:

The corresponding metric spaces have different topological properties. A metric space with metric (1) is complete [for any sequence of its points {*x*_{n}} such that ρ_{1}(*x*_{n}, *x*_{m}) → 0 as *n, m* → ∞, we can find an element *x*_{0} of the metric space that is the limit of this sequence]; a metric space with metric (2) does not have this property. Fundamental concepts of analysis can be introduced in a metric space, such as the continuity of the mapping of one metric space into another, convergence, and compactness. The concept of metric space was introduced by M. Fréchet in 1906.

### REFERENCES

Aleksandrov, P. S.*Vvedenie v obshchuiu teoriiu mnozhestv i funktsii*. Moscow-Leningrad, 1948.

Kolmogorov, A. N., and S. V. Fomin.

*Elementy teorii funktsii i funktsional’nogo analiza*, 3rd ed. Moscow, 1972.

Liusternik, L. A., and V. I. Sobolev.

*Elementy funktsionaVnogo analiza*, 2nd ed. Moscow, 1965.

V. I. SOBOLEV

## metric space

(mathematics)1. For any point x, d(x,x)=0;

2. For any two distinct points x and y, d(x,y)>0;

3. For any two points x and y, not necessarily distinct,

d(x,y) = d(y,x).

4. For any three points x, y, and z, that are not necessarily distinct,

d(x,z) <= d(x,y) + d(y,z).

The distance from x to z does not exceed the sum of the distances from x to y and from y to z. The sum of the lengths of two sides of a triangle is equal to or exceeds the length of the third side.